Process for production of ammonium thiosulphate

ABSTRACT

A process for continuous production of ammonium thiosulphate, (NH 4 ) 2 S 2 O 3  (ATS) from NH 3 , H 2 S and SO 2  is disclosed. A first feed stream comprising H 2 O, H 2 S and NH 3  with a molar H 2 S:NH 3  ratio &lt;0.4 is partially condensed to form a condensate. The condensate is contacted with a third feed gas comprising H 2 S and the gas stream comprising NH 3  and H 2 S is passed to a mixing device where the gas stream is dissolved in water drained off from an aerosol filter. A second feed gas stream comprising approximately ⅔ mole SO 2  per mole of NH 3  contained in the first feed stream is passed to a SO 2  absorber. The aqueous solution produced in mixing device is contacted with the SO 2  absorber.

This is a continuation-in-part of U.S. application Ser. No. 09/938,519, filed Aug. 27, 2001, now abandoned.

INTRODUCTION

The present invention relates to a process for continuous production of a concentrated solution of ammonium thiosulfate (ATS) from off gases comprising H₂S and NH₃ such as refinery SWS (Sour Water Stripper)-gas, which contains NH₃ as well as H₂S and H₂S gas streams.

The process according to the invention is distinguished by utilizing only the NH₃ in the SWS gas for the production of high purity ATS solution, thus producing 7.25 kg 60% ATS solution per kg of NH₃ in the SWS gas treated in the process. Furthermore, when the process according to the invention uses the effluent gas of a Claus plant as SO₂-source for the process, the total sulphur-recovery of the Claus plant and the ATS plant taken together is increased to more than 99.95% with only 86–95% sulphur recovery being required in the Claus plant.

BACKGROUND AND OBJECTIVE FOR THE INVENTION

It is known to produce aqueous solutions of ATS by reacting a solution of ammonium sulphite with sulphur in liquid form or with sulphides or polysulphides in aqueous solution as described in Kirk-Othmer Encyclopedia of Chemical Technology, 4^(th) edition, 1997, vol 24, page 62 and in U.S. Pat. Nos. 2,412,607; 3,524,724 and 4,478,807.

It is furthermore known from U.S. Pat. No. 3,431,070 to produce ATS in a continuous process from gaseous feed streams comprising H₂S, NH₃ and SO₂. By the process of this invention ATS and sulphur is produced from a first feed gas stream comprising H₂S and NH₃ and a second feed gas stream comprising SO₂ in three absorption steps. In a first absorber, NH₃ and H₂S are separated in a H₂S off-gas stream and an NH₃-rich solution of ATS. The main part of the solution is passed to a second absorber, in which it is contacted with the SO₂-rich feed gas stream under formation of an off-gas that is vented and a solution rich in ATS and ammonium sulphites, which in a third absorber is contacted with the H₂S-gas from the first absorber and, optionally, with additional H₂S. After removal of sulphur being formed in the third absorber, the major part of the ATS-solution formed in the third absorber is recycled to the first absorber, while a minor part is mixed with a fraction of the NH₃-rich solution of ATS formed in the first absorber forming the product solution of ATS.

There are three major disadvantages of this process: Elementary sulphur is formed in the third absorber and must be separated from the solution, the off-gas vented from the third absorber has a high concentration of H₂S and the process is complicated with three integrated absorption steps.

It is also known from EP 0 928 774 A1 to produce an aqueous solution of ATS from gaseous feed streams comprising NH₃, H₂S and possibly SO₂. By the process of this patent, a concentrated solution of ammonium hydrogen sulphite (AHS) is produced from NH₃ and SO₂ in a first absorption step comprising one or two absorbers in series. Said solution is contacted in a second absorption step with a gaseous mixture of H₂S and NH₃ forming the product solution of ATS.

The major disadvantage of this process is that it requires import of NH₃ for the process.

Furthermore, a process is known from Danish Patent No. 174407, wherein ATS is produced by using only the NH₃ contained in the SWS-gas stream as the NH₃ source for ATS-production.

In said process a first feed stream, typically SWS-gas, comprising more than 0.33 mole H₂S per mole of NH₃ is contacted with a stream of sulphite solution in line 18 in the drawing FIG. 1 and FIG. 2 in said patent application in a reactor A1 for formation of ATS. However, experiments have shown that the presence of excess H₂S for the formation of ATS from sulphites in the reactor will lead to the presence of free sulphide in the product solution (line 12), part of which is recycled (line 17) to the SO₂ absorber (A2), in which the sulphide will be decomposed to give H₂S in the absorber effluent gas (line 19). Furthermore, the large recycle of solution (line 13) to the SO₂ absorber and back to the reactor (lines 17–18) is also a disadvantage of the process.

The objective of this invention is to establish an improved process for the production of ATS in which over 99.9% of all sulphur and all NH₃ in the feed streams are recovered as ATS without any of the above mentioned disadvantages.

SUMMARY OF THE INVENTION

This invention relates to a process for continuous production of ammonium thiosulphate, (NH₄)₂S₂O₃ (ATS) from NH₃, H₂S and SO₂ comprising following steps:

(a) partial condensation in a partial condenser 4 of a first gaseous or partial liquid feed stream comprising H₂O, H₂S and NH₃ with a molar H₂S:NH₃ ratio <0.4, preferably in the range 0.1–0.25;

(b) passing the aqueous condensate comprising NH₄HS and NH₃ from the partial condenser 4 through line 5 to a reactor 9 in which said condensate is contacted with a third feed gas stream comprising H₂S supplied through line 7 and with an aqueous solution comprising NH₄HSO₃ (AHS) and (NH₄)₂SO₃ (DAS) supplied through line 10 under formation of an aqueous solution of ATS being removed from the reactor through line 12;

(c) passing the gas stream comprising NH₃ and H₂S from the partial condenser 4 through line 6 to a mixing device 13 in which said gas stream is completely dissolved in the water that is drained off from the aerosol filter 25 and passed to 13 through the line 26;

(d) passing a second feed gas stream in line 20 comprising in principle ⅔ mole SO₂ per mole of NH₃ comprised in the first feed stream to a SO₂ absorber 21 and the aerosol filter 25;

(e) passing the aqueous solution produced in mixing device 13 through line 14 to the SO₂ absorber 21;

(f) passing the off gas from absorber 21 through line 23 and 24 to an aerosol filter 25 to which is added, through line 30, the balance amount of water required for obtaining about 60 wt % (40–65 wt %) ATS in the aqueous solution removed from the reactor 9 in line 12.

Step (e) can preferably be carried out by adding said aqueous solution to the liquid recycle loop 27 of the SO₂-absorber.

These and other features and advantages of the invention will be more apparent from the following detailed description that is provided in connection with the accompanying drawings and illustrated exemplary embodiments of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates the formation of ammonium thiosulphate in accordance with an exemplary process of the present invention; and

FIG. 2 illustrates the formation of ammonium thiosulphate incorporating a Claus plant and in accordance with the exemplary process of the present invention shown in FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION

Referring to the drawing FIG. 1, a first feed stream of fractionated SWS-gas in line 1 comprising, for example, 6 kmole/h NH₃ associated with 1.1 kmole/h H₂S and 2 kmole/h H₂O, is treated with a second feed gas stream in line 20 comprising SO₂ associated with water vapor and inert components such as N₂, CO₂ and O₂ and a 3d feed gas stream comprising H₂S in line 7. Feed water required for the process is fed in line 30 to the aerosol filter 25. Some feed water may also be added in line 2 to the first feed gas stream. More than 99.95% of the amounts of NH₃ and SO₂ in the feed streams are recovered in the product ATS stream exiting the process in line 36. Thus, the off gas from the process in line 29 contains a negligible amount of SO₂ and essentially no NH₃ and H₂S.

The original SWS-gas available in refineries usually have a molar H₂S:NH₃ ratio of about 1:1, which is higher than directly acceptable for the process. Therefore, the original SWS-gas must first be fractionated by known methods in columns not shown on the figure to give a feed gas stream in line 1 with less than about 0.35 mole H₂S per mole of NH₃ in the feed gas, preferably with a H₂S:NH₃ molar ratio in the range of 0.1–0.25. The two other off streams (not shown in FIG. 1) from said fractionation are H₂S, which can be used as make-up for stream 7, and practically pure water. Experiments with the process have shown that with H₂S:NH₃>about 0.35 in stream 1, it will be very difficult or impossible to avoid presence of free sulphide in the ATS product stream in line 36 and/or presence of H₂S in the process exit gas in line 29. A H₂S:NH₃ ratio of about 1.1:6=0.18 in feed stream 1 seems very suitable for conducting the process according the invention.

The amounts of H₂S, SO₂ and H₂O comprised in the feed streams for production of a 60% ATS solution from 6 kmole NH₃ in the first feed stream are calculated from the mass balance of the over-all process: 6 NH₃+4 SO₂+2 H₂S+17.5 H₂O→3 (NH₄)₂S₂O₃+16.5 H₂O,  Eguation (1): corresponding to the following amounts in kg: 102.14 kg NH₃+256.24 kg SO₂+68.16 kg H₂S+315.32 kg H₂O.  Equation (1a): give 741.86 kg 60% ATS solution.

The first feed stream comprising 6 kmole NH₃, 1.1 kmole H₂S and 2 kmole H₂O in line 1 is cooled in the cooler 3 to a temperature between 20° C. and 60° C., or well below its dew point upstream of the partial condenser 4. In the partial condenser 4 the first feed stream is separated in an aqueous solution exiting in line 5 comprising NH₄HS and some NH₃ dissolved in practically all of the water in the feed stream 1, and in a gas phase exiting in line 6 comprising most of the NH₃ (approximately 4.6 kmole NH₃) and a small amount of H₂S (approximately 0.1 kmole H₂S). Water may be added in line 2 upstream of 4, but in the example the amount of water added to the process at this point is chosen to be zero. The liquid stream 5 comprising in the example 1.0 kmole NH₄HS, 0.4 kmole NH₃ and 2 kmole H₂O goes to the reactor 9 in which it is reacted with (0.9+x) kmole H₂S, the third feed stream and as defined below, introduced in line 7 and with the liquid sulphite stream 10 comprising 0.15 kmole ATS, 3.3 kmole AHS (NH₄HSO₃), 0.5 kmole DAS ((NH₄)₂SO₃) and 11.65 kmole H₂O. In the reactor 9 ATS will be formed by the principal reactions: 4 NH₄HSO₃+2 NH₃+2H₂S

3 (NH₄)₂S₂O₃+3H₂O  Equation (2): 4 (NH₄)₂SO₃+2 H₂S

3 (NH₄)₂S₂O₃+2 NH₃+3H₂O  Equation (3): resulting in formation of 741.8 kg of 60% ATS solution leaving the reactor through line 12.

An excess amount of x kmole H₂S may be added to the feed stream of 0.9 kmole H₂S, which constitutes the third feed gas stream, in line 7 in order to increase the rates of reactions 2 and 3. The x kmole H₂S, which may constitute 0–10% of equivalent amount of H₂S required for the process, is vented from the reactor through the vent line 11.

Additional sulphite solution may be added through line 35 to the ATS product solution having e.g. a composition of 60% ATS (3 kmol ATS and 16.5 kmol water), in order to complete the conversion to ATS of possible traces of sulphide or H₂S in the stream 12 and/or to add 0–2% DAS to the product ATS solution exiting the process in line 36. For simplicity, no sulphite is added through line 35 in the present example. pH of the solution in line 12 and in the reactor 9 will typically be in the range 7.6–8.6.

The off gas from 4 (4.6 kmol NH₃ and 0.1 kmol H₂S) is passed to the mixing device 13 in which it is completely dissolved in the aqueous stream 26 from the aerosol filter 25. Stream 26 will usually comprise at least 0.1 kmole AHS which reacts with the H₂S and NH₃ in stream 6 under formation of ATS according to for instance equation 2. A minor fraction of the sulphite solution exiting the SO₂-absorption is added to stream 26 through line 28 in order to ensure complete removal of all H₂S or sulphide in the aqueous stream 14 before it is added to the SO₂ absorption loop 27. Stream 28 may comprise a flow of sulphite (NH₄HSO₃) and (NH₄)₂SO₃ which, together with the sulphite in the off stream from the aerosol filter 25, relates to the flow of sulphide (H₂S+NH₃HS) in the stream from the condenser 4 by a molar ratio of 2:1 or more. Addition of excess ammonium sulphites through 28 will also keep pH in stream 14 below of about 9.2. If pH is higher than 9.2 in stream 14 (due to the high concentration of NH₃ in said stream), the formation of ATS from the sulphide may be inhibited leading to liberation of H₂S in the SO₂-absorber 21 and to presence of H₂S in the absorber off gas.

The flow of SO₂ (second feed gas stream) required for the process is in line 20 fed to the SO₂-absorber 21 in which the SO₂ is in principle absorbed by the NH₃ comprised in the NH₃-rich off gas in line 6 from the partial condensation in 4 of the feed stream 1. According to the over-all mass balance of the present example given in equation 1, 4.0 kmole SO₂ is required for the process. As the SO₂ feed stream is produced by upstream combustion of H₂S or other sulphurous components, the SO₂ in line 20 will be diluted with inert gas comprising N₂, CO₂ and O₂ and with water vapor. In FIG. 1 it is assumed that the 4 kmole SO₂ is diluted with approximately 100 kmole inert gases and 6 kmole H₂O corresponding to a H₂O dew point of 35–36° C.

The SO₂ absorber 21 is typically a fixed bed absorber where the absorption liquid is recycled in a loop 27 comprising a circulating pump and a cooler which maintains the temperature of absorption preferably at 35–40° C., whereby no net condensation or net evaporation of H₂O takes place in the absorber and in the subsequent aerosol filter 25. The pH value of the aqueous solution comprising NH₄HSO₃ and (NH₄)₂SO₃ used for absorption of SO₂ in the absorber 21 is adjusted between approximately 5 and approximately 7.5. The SO₂ absorber 21 may also be a packed column or a bubbling tank reactor.

In the example in FIG. 1, 15.5 kmole/h water is supplied to the aerosol filter 25 for instance by spraying the water on the filter candles. As there will be practically no NH₃, SO₂ or aerosols in the process off gas in line 29, the aqueous solution exiting the absorber in line 10 (after subtraction of the fraction taken out in line 28) can be calculated from the mass balances to be 617.2 kg/h solution comprising 0.15 kmole/h ATS, 3.3 kmole/h AHS, 0.5 kmole/h DAS and 11.65 kmole/h H₂O. The equilibrium partial pressures of NH₃ of this solution at 40° C. have been found to be approximately 10⁻³ bars higher than that of SO₂.

In order to recover this NH₃, 0.1 kmole SO₂ is added to the SO₂ absorber effluent gas by bypassing in line 22 about 0.1/4=2.5% of the gas flow in line 20 around the SO₂ absorber and adding said bypass stream to the absorber effluent gas in line 23. The NH₃ and SO₂ react in the gas phase forming an aerosol of AHS, which is removed in the filter 25. All aerosols present in the gas leaving the SO₂-absorber will also be removed and dissolved in the water supplied to the filter. The filter off gas in line 29 contains typically about 40 ppm SO₂, less than 2 ppm NH₃ and essentially no H₂S.

Separation in the partial condenser 4 of the fractionated SWS-feed gas stream in a gaseous NH₃-rich stream 6 and a liquid stream 5 is very advantageous but not strictly necessary for the process.

The separation can in principle be replaced by splitting stream 1 in a stream 5 being passed to 9 together with stream 7 and a stream 6 being mixed in 13 in principle as seen in FIG. 1.

The SO₂-absorption may also be carried out with two SO₂-absorbers connected in series, or the SO₂-absorber 21 may be a bubbling SO₂-absorber in which the feed gas in line 20 is bubbled through the absorbing solution with or without external circulation in a loop 27 as shown in FIG. 1.

A fraction of the second feed gas stream can be by-passed the absorber 21 and mixed with the effluent gas from the absorber 21 upstream of the aerosol filter 25. The fraction can contain 0.7–1.3 moles of SO₂ per mole of NH₃ contained in the off gas from the SO₂-absorber 21.

Essentially complete conversion of sulphide to (NH₄)₂S₂O₃ in the process and a desired concentration of excess (NH₄)₂SO₃ and NH₄HSO₃ of 0–2 wt % in the product exit stream 36 are achieved (1) by adjusting the feed rate of H₂S in line 7 to give a small stream in line 11 of excess H₂S in the range of 0–10% of the equivalent amount of H₂S for the production of ATS and (2) by bypassing a minor fraction of stream 10 through line 35 to stream 12. In other words, the feed rate of H₂S in the third feed stream 7 is adjusted to give an excess effluent H₂S stream from the reactor 9 of 0–10% of the equivalent amount of H₂S for the production of (NH₄)₂S₂O₃ and a fraction 10 of the solution produced in the SO₂ absorber 21 is bypassed to the (NH₄)₂S₂O₃ solution withdrawn from the reactor 9.

Use of the present ATS process is in particular advantageous when the off gas from a Claus plant is used as source for the SO₂ required for the process. This is seen in the overview in FIG. 2 of sulphur recovery with a simple Claus process combined with the present ATS process in a refinery producing H₂S and SWS-gas from various hydrogenation and cracking treatments of hydrocarbons. Without use of the ATS process all H₂S and SWS gas had to be treated in the Claus plant and the ammonia had to be decomposed at substantial costs. No more than 95–97% sulphur recovery can be achieved in simple 2 or 3-bed Claus plants. Higher degrees of sulphur recovery require expensive processes for tail gas treatment. Increasing the sulphur recovery to more than 99% by known processes is very expensive investment wise as well as with regard to operating costs and energy consumption. However, 99.95% total sulphur recovery or more is automatically achieved with no increase in operating costs and energy consumption by utilizing the off gas from a simple 2-bed Claus plant as the SO₂-source for the present ATS process utilizing the SWS-gas for ATS-production, as shown in the schematic drawing in FIG. 2.

Referring to FIG. 2, the SWS gas containing e.g. 1 kmol ammonia and 1 kmol hydrogen sulphide, in line 51 is sent to a fractionation unit 52, in which it is split into an H₂S -rich stream 53 having e.g. ⅔ kmol hydrogen sulphide, and an NH₃-rich stream 54 containing all the NH₃ and approximately 0.33 mole H₂S per mole NH₃. The H₂S -rich stream 53 is mixed with an H₂S gas having e.g. 9 kmol hydrogen sulphide, in line 55 and sent to a Claus plant 56, in which most of the H₂S is recovered as sulphur in line 57. Air is also required in the Claus plant 56 and steam is produced. The sulphur recovery can be e.g. more than 93.1%. The off-gas from the Claus plant is sent to a tail gas incinerator 58, in which the H₂S is combusted to SO₂ with an excess of air. Steam is produced. A fraction of the Claus feed gas is bypassed (hydrogen sulphide bypass) around the Claus plant in line 59 to the tail gas incinerator and combusted to SO₂. The bypass flow in line 59 is adjusted to give approximately ⅔ mole SO₂ in the off-gas from the incinerator in line 510 per mole NH₃ contained in the SWS gas in line 51. In order to produce concentrated ATS solution, a fraction of the water contained in the off-gas from the incinerator is removed in a condensation step 511. The H₂O content of the off-gas from the condensation step is reduced to 3–10 vol % H₂O, preferably 6 vol % H₂O. The off-gas from the condensation step containing approximately ⅔ mole SO₂ is sent to the ATS process 512 according to the present invention, in which the SO₂ is removed by reaction with the NH₃-rich stream 54 from the fractionation unit 52. The purified gas stream 513 is vented through the stack and the product ATS solution (e.g. a 60% solution with 0.5 kmol ATS) is recovered in line 514. 

1. A process for continuous production of ammonium thiosulphate, (NH₄)₂S₂O₃ (ATS) from NH₃, H₂S and SO₂ comprising steps of: (a) partial condensation in a partial condenser of a first gaseous or partial liquid feed stream comprising H₂O, H₂S and NH₃ with a molar H₂S:NH₃ ratio <0.4; (b) passing the aqueous condensate comprising NH₄HS and NH₃ from the partial condenser to a reactor in which said condensate is contacted with a third feed gas stream comprising H₂S and with an aqueous solution comprising NH₄HSO₃ and (NH₄)₂SO₃ under formation of an aqueous solution of (NH₄)₂S₂O₃; (c) passing the gas stream comprising NH₃ and H₂S from the partial condenser to a mixing device in which said gas stream is completely dissolved in the water drained off from an aerosol filter; (d) passing a second feed gas stream comprising approximately ⅔ mole SO₂ per mole of NH₃ contained in the first feed stream to a SO₂ absorber and the aerosol filter; (e) passing the aqueous solution produced in mixing device to the SO₂ absorber; (f) passing the off gas from the absorber to the aerosol filter; and (g) adding to the aerosol filter a balance amount of water required for obtaining approximately 40–65 wt % (NH₄)₂S₂O₃ in the aqueous solution of (NH₄)₂S₂O₃ being withdrawn from the reactor.
 2. The process of claim 1, wherein the first feed stream of step (a) is divided into a substream being passed to the mixing device and a further substream which is contacted in the reactor with the third feed stream comprising H₂S and with an aqueous solution comprising NH₄HSO₃ and (NH₄)₂SO₃ under formation of an aqueous solution of (NH₄)₂S₂O₃.
 3. The process of claim 1, wherein a fraction of the second feed gas stream is by-passed the absorber and mixed with the effluent gas from the absorber upstream of the aerosol filter, said fraction containing 0.7–1.3 moles of SO₂ per mole of NH₃ contained in the off gas from the SO₂-absorber.
 4. The process of claim 1, wherein the SO₂-absorber is a packed column.
 5. The process of claim 1, wherein the SO₂-absorber is a bubbling tank reactor with or without external liquid recycle.
 6. The process of claim 1, wherein a fraction of the solution comprising NH₄HSO₃ and (NH₄)₂SO₃ produced in the SO₂-absorber is passed to the mixing device, said fraction of the solution comprising a flow of sulphite (NH₄HSO₃ and (NH₄)₂SO₃) which together with the sulphite in the off stream from the aerosol filter relates to the flow of sulphide (H₂S+NH₃HS) in the stream from the condenser by a molar ratio of 2:1 or more.
 7. The process of claim 1, wherein the second feed gas stream is an effluent gas stream from a Claus plant which is incinerated and its H₂O-content reduced to 3–10 vol % H₂O by cooling and partial condensation of its content of H₂O upstream of said process.
 8. The process of claim 1, wherein the first feed stream is Sour Water Stripper gas having been fractionated and adjusted to contain H₂S and NH₃ to a molar ratio of H₂S:NH₃ of <0.4.
 9. The process of claim 1, wherein the pH value of the aqueous solution comprising NH₄HSO₃ and (NH₄)₂SO₃ used for absorption of SO₂ in the absorber is adjusted between approximately 5 and approximately 7.5.
 10. The process of claim 1, wherein the feed rate of H₂S in the third feed stream is adjusted to give an excess effluent H₂S stream from the reactor of 0–10% of the equivalent amount of H₂S for the production of (NH₄)₂S₂O₃ and a fraction of the solution produced in the SO₂ absorber is bypassed through line to the (NH₄)₂S₂O₃ solution withdrawn from the reactor. 